Electrospun Nanofibrous Architectures of Thrombin-Loaded Poly(ethylene oxide) for Faster in Vivo Wound Clotting

Wound healing materials to prevent blood loss are crucial during emergency medical treatment because uncontrolled bleeding can lead to patient death. Herein, bioabsorbable fibrous architectures of thrombin-loaded poly(ethylene oxide)-PEO/thrombin-are conceptualized and accomplished via electrospinning for faster wound clotting. Membranes with average fiber diameters ranging from 188 to 264 nm are achieved, where the active thrombin is entrapped within the nanofibers. The results of in vitro and in vivo wound healing activity tests revealed that when the nanofibers with thrombin-loaded capacity are in contact with the wound, the presence of water in the skin or blood catalyzes the degradation of the membranes, thus releasing thrombin. Thrombin then accelerates the wound clotting process. In contrast to other hemostatic materials, PEO/thrombin nanofibers do not require mechanical removal after application, and the viscoelastic nature of such biomaterials enables their conformation to a variety of wound topographies. Remarkably, PEO/thrombin membranes are promising functional materials and their use is a powerful strategy for hemostatic treatment, ranging from simple first aid and sealing to a wound to small surgical procedures.

Automated summary

The study developed bioabsorbable fibrous architectures loaded with thrombin for faster wound clotting. These membranes degraded in the presence of water in the skin or blood, releasing thrombin and accelerating the wound clotting process. The viscoelastic nature of the biomaterials allowed them to conform to a variety of wound topographies, making them promising functional materials for hemostatic treatment.